Coevolution of Persistently Infecting Small DNA Viruses and Their Hosts

Coevolution of Persistently Infecting Small DNA Viruses and Their Hosts

Proc. Natl. Acad. Sci. USA Vol. 90, pp. 4117-4121, May 1993 Evolution Coevolution of persistently infecting small DNA viruses and their hosts linked to host-interactive regulatory domains (polyomavirus/papillomavirus/parvovirus/retinoblastoma protein/p53 protein) F. F. SHADAN AND Luis P. VILLARREAL Department of Molecular Biology and Biochemistry, University of California, Irvine, CA 92717 Communicated by Francisco J. Ayala, January 8, 1993 ABSTRACT Although most RNA viral genomes (and re- transcriptase-mediated, vertically transmitted transposable el- lated cellular retroposons) can evolve at rates a millionfold ements (cellular retroposons) appear to result in a dislinkage greater than that of their host genomes, some of the small DNA from the much slower rates of host species evolution (for viruses (polyomaviruses and papillomaviruses) appear to evolve review see ref. 5). Yet high rates of evolution and adaptation at much slower rates. These DNA viruses generally cause host to cause disease may not be a characteristic ofall viral families. species-specific inapparent primary infections followed by life- Some virus families (especially the small DNA viruses, long, benign persistent infections. Using global progressive including the Polyomaviridae, Papillomaviridae, and some sequence alignments for kidney-specific Polyomaviridae (mouse, Parvoviridae), however, appear to be relatively stable genet- hamster, primate, human), we have constructed parsimonious ically and also may not fit a predator-prey population model. evolutionary trees for the viral capsid proteins (VP1, VP2/VP3) In contrast to many RNA and some other viruses, the small and the large tumor (T) antigen. We show that these three coding DNA viruses generally cause inapparent primary infections sequences can yield phylogenetic trees similar to each other and followed by lifelong persistent infection with little disease to that of their host species. Such virus-host "co-speciation" (12-14). Also, unlike rapidly evolving RNA viruses, these appears incongruent with some prevailing views of viral evolu- DNA viruses replicate by using host error-correcting DNA tion, and we suggest that inapparent persistent infections may replication processes which are thought to result in low error link virus and most host evolution. Similarity analysis identified rates and account for much of their genetic stability. Yet three specific regions of polyoma regulatory gene products (T genetic stability is not necessarily inherent to replication of antigens) as highly conserved, and two of these regions corre- small DNA viruses. The capsid gene of canine distemper spond to binding sites for host regulatory proteins (p53, the virus (a parvovirus) can evolve at high rates, similar to the retinoblastoma gene product p105, and the related protein hemagglutinin (HA) gene of influenza (15). Nevertheless, the p107). The p53 site overlaps with a conserved ATPase domain genetic stability of small DNA viruses seems well estab- and the retinoblastoma site corresponds to conserved region 1 of lished, as exemplified by human papillomavirus type 16 ElA protein of adenovirus type 5. We examined the local (HPV16, specific to the genital epithelium). Worldwide iso- conservation of these binding sequences and show that the lates of this virus show remarkably little genetic variation conserved retinoblastoma binding domain is characteristic and during persistent infection (<5%) and are distributed in inclusive of the entire polyomavirus family, but the conserved geographic and population patterns similar to the distribution p53-like binding domain is characteristic and indusive of three and migration of major human racial populations (16). entire families of small DNA viruses: polyomaviruses, papillo- However, the genetic stability of HPV16 and its charac- maviruses, and parvoviruses. The evolution ofsmall-DNA-virus teristic host-dependent evolution become apparent only families may thus be tightly linked to host evolution and speci- when the analysis is restricted to viruses that infect the same ation by interaction with a subset of host regulatory proteins. tissue. In contrast, mixing HPVs ofdifferent tissue specificity results in a complex but binary phylogenetic tree (17). These two major HPV phylogenetic subgroups seem to be due to Disease-causing acute viral infections appear to affect host selection for growth in specific mucosal or cutaneous epi- populations in a manner similar to predator effects on prey thelial tissues and diverge from a putative archetypical HPV populations. This is seen with epidemic influenza, measles (17, 18). In analogy to this observation of tissue-specific virus, poxvirus, and, more recently, human immunodefi- papillomavirus evolution, we have concentrated our analysis ciency virus (for early review see refs. 1 and 2). During early on polyomaviruses that are capable of propagation in a human evolution, however, tribal extinction, isolation, or common host tissue, the kidney. Although most of the immunity should eradicate most acute viral diseases but polyomavirus family members do replicate preferentially in subacute or persisting viral infections could be maintained in kidneys [mouse polyomavirus, BK virus, JC virus, simian small human populations (3). It has been observed that pop- virus 40 (SV40), hamster polyomavirus], primary replication ulations of RNA viral genomes (4) [or retroviruses (5)] can in other tissue is also known (i.e., K polyomavirus in lung). evolve at extremely high rates, generating diverse genetic Alterations to regulatory DNA can also alter organ specificity compositions which may be considered as quasispecies (6, 7). of mouse polyomavirus replication (19), but this simple In addition, some chronic viral infections of individual hosts genetic adaption may be a biological dead end, as persistence show evolution of virus populations in apparent adaptation to and propagation of the infection does not occur (20). The host defenses, possibly leading to emergence ofdisease (8-10). human polyomaviruses (BK and JC viruses) have a highly The diversity, adaptability, and rapid evolution of these and variable regulatory sequence when grown in vitro, but this other parasites has been proposed to be an important driving sequence is stably maintained by unknown mechanisms force in the evolution of the host, including the origin of sex during persistent human infection (21, 22). (11). Such high evolutionary rates of viruses and reverse- Abbreviations: Ad, adenovirus; CR, conserved region; HPV, human The publication costs of this article were defrayed in part by page charge papillomavirus; NCBI, National Center for Biotechnology Informa- payment. This article must therefore be hereby marked "advertisement" tion; PIR, Protein Identification Resource; Rb, retinoblastoma pro- in accordance with 18 U.S.C. §1734 solely to indicate this fact. tein; SV40, simian virus 40. 4117 Downloaded by guest on September 29, 2021 4118 Evolution: Shadan and Villarreal Proc. Natl. Acad. Sci. USA 90 (1993) As a rule, polyomavirus and papillomavirus families are Identification Resource (PIR) were analyzed by global pro- host species-specific for replication (23), ubiquitous [even in gressive sequence alignment (38) to construct parsimonious nongregarious hosts (24, 25)], and cause inapparent or mild evolutionary trees (Fig. 1). As described by the EUGENE primary infections in young animals, followed by lifelong, manual (Molecular Biology Information Resource, Baylor nonpathogenic, persistent maintenance of nonintegrated, College of Medicine), the program builds a preliminary nondefective, episomal viral DNA (26, 27). Some pathogenic phylogenetic tree, by the method of Klotz and Blanken (39), versions [such as avian polyomavirus (28) and mouse K virus from distance measures calculated in pairwise (29)] exist, but these are not characteristic of most infections comparisons (12). Even parvoviruses, which are most frequently associ- of all sequences to be analyzed. A final tree is constructed ated with acute disease, most often cause inapparent and from distances calculated from aligned sequences. All se- persistent infections (13, 30). Thus, silent persistent infec- quences are aligned pairwise using the SS2 algorithm of tions with little apparent affect on the host's health are more Altschul and Erickson (40), a method which finds the align- characteristic of these virus families. ment having the minimum total cost from the Dayhoff cost The species-specific replication of small DNA viruses im- matrix. The penalty for opening a gap was set to 2.5 and the plies a possible linkage to the molecular processes of host incremental penalty for each space was set to 0.5. speciation. The molecular basis of this species-specific repli- Similarity Analysis of Putative Rb- and p53-Like Binding cation has been examined only with mouse polyomavirus and Regions (Figs. 2 and 3). The National Center for Biotechnol- monkey SV40 (23) and appears to be due to the binding of the ogy Information (NCBI), nonredundant protein database viral (early protein) T-antigen/DNA complex to cellular p53 (PIR 31.0, January 26, 1992) was probed by the BLAST (31) regulatory protein and cellular DNA polymerase-primase program, using the complete amino acid sequence (738 res- complex, resulting in species-specific initiation of viral DNA idues) of the mouse polyomavirus (A2) large T antigen. The synthesis (32, 33). In addition to p53, the regulatory proteins neighborhood word score threshold (T) and the cutoff score ofmany

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